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| university:courses:electronics:electronics-lab-external-trigger [14 Dec 2018 11:50] – add Fritzing files Antoniu Miclaus | university:courses:electronics:electronics-lab-external-trigger [11 Feb 2021 19:14] (current) – Ioana Chelaru |
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| =====Hardware Setup:===== | =====Hardware Setup:===== |
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| Waveform generator AWG1 should be set up as a triangle wave with a 8 Volt amplitude and 0 V offset and a frequency of 5 KHz. Set the horizontal and vertical scales of the scope to display at least one complete cycle of the input triangle waveform. Turn on the power supplies only after double checking your circuit connections. | Waveform generator AWG1 should be set up as a triangle wave with a 8 Volt amplitude peak-to-peak and 0 V offset and a frequency of 5 KHz. Set the horizontal and vertical scales of the scope to display at least one complete cycle of the input triangle waveform. Turn on the power supplies only after double checking your circuit connections. |
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| {{ :university:courses:electronics:adjustableexternaltriggering_hardwaresetup1.png |}} | {{ :university:courses:electronics:adjustableexternaltriggering_hardwaresetup1.png |}} |
| ====For Further Reading:==== | ====For Further Reading:==== |
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| [[http://www.analog.com/static/imported-files/faqs/vol23n4.pdf|Ask The Applications Engineer]] - High-speed comparators provide many useful circuit functions when used correctly. | [[adi>media/en/technical-documentation/frequently-asked-questions/vol23n4.pdf|Ask The Applications Engineer]] - High-speed comparators provide many useful circuit functions when used correctly. |
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| [[http://www.analog.com/library/analogDialogue/archives/34-07/comparators/comparators.pdf|Curing Comparator Instability with Hysteresis]] | [[adi>library/analogDialogue/archives/34-07/comparators/comparators.pdf|Curing Comparator Instability with Hysteresis]] |
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| **Return to Activity [[university:courses:electronics:labs|Table of Contents]].** | **Return to Activity [[university:courses:electronics:labs|Table of Contents]].** |
| The second Inverter is made by connecting pin 2 to V<sub>DD</sub>, pin 4 to V<sub>SS</sub>, pins 1 and 5 are connected together as the output and with pin 3 as the input. The third inverter is made by connecting pin 11 to V<sub>DD</sub>, pin 9 to V<sub>SS</sub>, pin 12 is the output and pin 10 is the input. | The second Inverter is made by connecting pin 2 to V<sub>DD</sub>, pin 4 to V<sub>SS</sub>, pins 1 and 5 are connected together as the output and with pin 3 as the input. The third inverter is made by connecting pin 11 to V<sub>DD</sub>, pin 9 to V<sub>SS</sub>, pin 12 is the output and pin 10 is the input. |
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| | <WRAP round download> |
| **Resources:** | **Resources:** |
| * Fritzing files: [[ https://minhaskamal.github.io/DownGit/#/home?url=https://github.com/analogdevicesinc/education_tools/tree/master/m2k/fritzing/adjust_ext_trigger_bb | adjust_ext_trigger_bb]] | * Fritzing files: [[downgit>education_tools/tree/master/m2k/fritzing/adjust_ext_trigger_bb | adjust_ext_trigger_bb]] |
| | </WRAP> |
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